Advanced electrospun chitosan-(polylactic acid)-(silver nanoparticle)-based scaffolds for facilitated healing of purulent wounds: a preclinical investigation

Yevhen Samokhin; Yuliia Varava; Anna Butsyk; Roman Moskalenko; Yevheniia Husak; Bohdan Dryhval; Valeriia Korniienko; Ihor Zhyvotovskyi; Vyacheslav Kukurika; Artem Shmatkov; Agnė Ramanavičiūtė; Rafal Banasiuk; Maksym Pogorielov; Arūnas Ramanavičius; Viktoriia Korniienko

doi:10.3390/polym17162225

Title	Advanced electrospun chitosan-(polylactic acid)-(silver nanoparticle)-based scaffolds for facilitated healing of purulent wounds: a preclinical investigation
Authors	Samokhin, Yevhen ; Varava, Yuliia ; Butsyk, Anna ; Moskalenko, Roman ; Husak, Yevheniia ; Dryhval, Bohdan ; Korniienko, Valeriia ; Zhyvotovskyi, Ihor ; Kukurika, Vyacheslav ; Shmatkov, Artem ; Ramanavičiūtė, Agnė ; Banasiuk, Rafal ; Pogorielov, Maksym ; Ramanavičius, Arūnas ; Korniienko, Viktoriia
DOI	10.3390/polym17162225
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Is Part of	Polymers.. Basel : MDPI. 2025, vol. 17, iss. 16, art. no. 2225, p. [1-20].. eISSN 2073-4360
Keywords [eng]	antimicrobial biomaterials ; chitosan ; electrospinning ; polylactic acid ; purulent wounds ; silver nanoparticles ; wound healing
Abstract [eng]	Biomaterials modified by antibacterial substances, including nanoparticles, open new opportunities for the effective treatment of infected wounds. Unfortunately, most publications focused only on experiments in vitro, with limited understanding of their potential for the clinic. This study evaluates the effectiveness in vivo of electrospun chitosan/polylactic acid (Ch/PLA) membranes enriched with silver nanoparticles (AgNPs) for purulent wound treatment. The composite biomaterial integrates chitosan’s biocompatibility and antimicrobial activity with PLA’s structural integrity, while AgNPs enhance antibacterial efficacy against major wound pathogens, including Staphylococcus aureus, Pseudomonas aeruginosa, and Escherichia aureus. A full-thickness purulent wound model was established in a rat model, and the animals were divided into three treatment groups: (i) Ch/PLA, (ii) Ch/PLA-AgNPs, and (iii) PLA-chlorhexidine (control). Wound healing was monitored over 21 days through macroscopic evaluation, histology, immunohistochemistry, and microbiological analysis. The Ch/PLA-AgNPs membranes significantly reduced bacterial colonization within 4–6 days, promoted granulation tissue formation, and accelerated epithelialization compared to the non-modified Ch/PLA scaffold. By day 15, complete wound closure was observed in the Ch/PLA-AgNPs group, comparable to PLA-chlorhexidine-treated wounds. Immunohistochemical analysis revealed a controlled inflammatory response with a balanced macrophage M1/M2 transition, supporting efficient tissue regeneration. Furthermore, systemic toxicity assessments indicated no significant adverse effects on internal organs. These findings demonstrate that electrospun Ch/PLA-AgNPs membranes effectively accelerate purulent wound healing by combining antimicrobial protection with biocompatible tissue support. This innovative approach presents a promising alternative to conventional wound dressings and paves the way for clinical applications in managing infected wounds.
Published	Basel : MDPI
Type	Journal article
Language	English
Publication date	2025
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„Advanced electrospun chitosan-(polylactic acid)-(silver nanoparticle)-based scaffolds for facilitated healing of purulent wounds: a preclinical investigation“